Legal claims defining the scope of protection. Each claim is shown in both the original legal language and a plain English translation.
1. A transmitting apparatus comprising: a first signal outputter configured to output a first signal to a receiving apparatus via a first line; and a communicator connected to a second line that connects a receiving-side ground node and the first signal outputter with an AC connection, the receiving-side ground node being configured to be supplied with a ground potential of the receiving apparatus, and the communicator being configured to transmit a second signal from the transmitting apparatus to the receiving apparatus by causing a direct current, having a magnitude configured to change based on a logic level of the second signal, to flow in the second line, or being configured to receive the second signal from the receiving apparatus by detecting a magnitude of a direct current flowing in the second line.
This invention relates to a transmitting apparatus designed to communicate with a receiving apparatus using both AC and DC signals over separate lines. The apparatus includes a first signal outputter that sends a first signal to the receiving apparatus via a first line. Additionally, a communicator is connected to a second line, which links a receiving-side ground node (supplied with the receiving apparatus's ground potential) to the first signal outputter. The communicator enables bidirectional communication by modulating a direct current (DC) in the second line based on the logic level of a second signal. For transmission, the communicator adjusts the DC magnitude to encode the second signal, while for reception, it detects the DC magnitude to decode incoming signals. This dual-line approach allows simultaneous AC signal transmission and DC-based communication, improving data transfer efficiency and reducing interference. The system is particularly useful in applications requiring high-speed data communication alongside traditional signal transmission.
2. The transmitting apparatus according to claim 1 , wherein the communicator is a first communicator, the receiving apparatus includes a second communicator connected to the second line, the second communicator being configured to transmit the second signal from the receiving apparatus to the transmitting apparatus by causing a direct current, having a magnitude configured to change based on the logic level of the second signal, to flow in the second line, or being configured to receive the second signal from the transmitting apparatus by detecting a magnitude of a direct current flowing in the second line, the first signal outputter is configured to generate the first signal by canceling an AC potential difference from an input signal, on which the AC potential difference is multiplexed, by being connected to the ground potential of the receiving apparatus via the second line, the AC potential difference being an alternating potential difference between a ground potential of the transmitting apparatus and the ground potential of the receiving apparatus, and a first impedance of the first communicator when viewed from the second line is higher than a second impedance of the second communicator when viewed from the second line.
3. The transmitting apparatus according to claim 2 , wherein the first communicator includes a constant current circuit configured to cause the direct current, having the magnitude configured to change based on the logic level of the second signal, to flow in the second line.
4. The transmitting apparatus according to claim 1 , wherein the communicator is configured to transmit the second signal of a predetermined logic level from the transmitting apparatus to the receiving apparatus by causing no direct current to flow in the second line, or is configured to receive the second signal of the predetermined logic level from the receiving apparatus by detecting no direct current flowing in the second line.
This invention relates to a transmitting apparatus for communicating with a receiving apparatus using a differential signaling scheme. The problem addressed is the need for efficient and reliable signal transmission in differential signaling systems, particularly when transmitting signals of a predetermined logic level without direct current (DC) flow in the second line of the differential pair. The transmitting apparatus includes a communicator that transmits a second signal of a predetermined logic level to the receiving apparatus by ensuring no direct current flows in the second line. Alternatively, the communicator receives the second signal of the predetermined logic level from the receiving apparatus by detecting the absence of direct current in the second line. This approach reduces power consumption and simplifies circuit design by avoiding unnecessary DC current flow while maintaining signal integrity. The invention builds on a base transmitting apparatus that already includes a communicator for transmitting and receiving signals between the transmitting and receiving apparatuses. The communicator is configured to handle differential signals, where the second signal is part of a differential pair. The absence of DC current in the second line during transmission or reception of the predetermined logic level ensures compatibility with low-power and high-speed communication requirements. This method is particularly useful in applications where minimizing power consumption and maintaining signal fidelity are critical, such as in high-speed data transmission systems.
5. A transmitting apparatus comprising: a first signal outputter connected to a second line that is connected with an AC connection to a receiving-side ground node, the receiving-side ground node being configured to be supplied with a ground potential of a receiving apparatus, the first signal outputter being configured to generate a first signal by canceling an AC potential difference from an input signal, on which the AC potential difference is multiplexed, by being connected to the ground potential of the receiving apparatus via the second line, the AC potential difference being an alternating potential difference between a ground potential of the transmitting apparatus and the ground potential of the receiving apparatus, and to output the first signal to the receiving apparatus via a first line; and a communicator that includes a constant current circuit configured to cause a direct current, having a magnitude configured to change based on a logic level of a second signal, to flow in the first line to thereby transmit the second signal from the transmitting apparatus to the receiving apparatus.
6. The transmitting apparatus according to claim 2 , wherein the first signal outputter includes an operational amplifier including: a positive input terminal; a negative input terminal; and an output terminal connected to the negative input terminal via a resistance element; the input signal is supplied to the negative input terminal via a resistance element, a bias potential is supplied to the positive input terminal via at least a resistance element, and Z 2 p /Z 1 p and Z 2 n /Z 1 n are substantially equal to each other, where Z 1 p is an impedance of a side of the second line when viewed from the positive input terminal, Z 2 p is an impedance of a supply side configured to supply the bias potential when viewed from the positive input terminal, Z 1 n is an impedance of a supply side configured to supply the input signal when viewed from the negative input terminal, and Z 2 n is an impedance of the output terminal when viewed from the negative input terminal.
7. The transmitting apparatus according to claim 2 , wherein the first signal outputter includes: an operational amplifier including: a negative input terminal; and a positive input terminal connected to the receiving-side ground node with an AC connection via a resistance element and the second line, the positive input terminal being configured to be supplied with a bias potential, on which the AC potential difference is multiplexed, via a resistance element; a differential signal generating circuit configured to generate, based on the input signal, both a positive-phase signal and an inverted-phase signal obtained by inverting the positive-phase signal; a first buffer circuit configured to supply the positive-phase signal to one of the positive input terminal and the negative input terminal of the operational amplifier via a resistance element; and a second buffer circuit configured to supply the inverted-phase signal to the other one of the positive input terminal and the negative input terminal of the operational amplifier via a resistance element, and the second buffer circuit having an output impedance substantially equal to an output impedance of the first buffer circuit.
8. The transmitting apparatus according to claim 2 , wherein the first signal outputter includes: an operational amplifier including: a negative input terminal; and a positive input terminal connected to the receiving-side ground node with an AC connection via a resistance element and the second line; a first buffer circuit configured to supply the input signal to the negative input terminal of the operational amplifier via a resistance element; and a second buffer circuit configured to apply a bias potential, on which the AC potential difference is multiplexed, to the positive input terminal of the operational amplifier via a resistance element, and the second buffer circuit having an output impedance substantially equal to an output impedance of the first buffer circuit.
9. A receiving apparatus comprising: a first signal inputter configured to receive a first signal from a transmitting apparatus via a first line; and a communicator connected to a second line that connects a transmitting-side ground node and the first signal inputter with an AC connection, the transmitting-side ground node being configured to be supplied with a ground potential of the transmitting apparatus, the communicator being configured to transmit a second signal from the receiving apparatus to the transmitting apparatus by causing a direct current, having a magnitude configured to change based on a logic level of the second signal, to flow in the second line, or being configured to receive the second signal from the transmitting apparatus by detecting a magnitude of a direct current flowing in the second line.
10. The receiving apparatus according to claim 9 , wherein the communicator is a second communicator, the transmitting apparatus includes a first communicator connected to the second line, the first communicator being configured to transmit the second signal from the transmitting apparatus to the receiving apparatus by causing a direct current, having a magnitude configured to change based on the logic level of the second signal, to flow in the second line, or being configured to receive the second signal from the receiving apparatus by detecting a magnitude of a direct current flowing in the second line, the first signal inputter is configured to generate an output signal by canceling an AC potential difference from the first signal, on which the AC potential difference is multiplexed, by being connected to the ground potential of the transmitting apparatus via the second line, the AC potential difference being an alternating potential difference between the ground potential of the transmitting apparatus and a ground potential of the receiving apparatus, and a second impedance of the second communicator when viewed from the second line is higher than a first impedance of the first communicator when viewed from the second line.
11. The receiving apparatus according to claim 10 , wherein the second communicator includes a constant current circuit configured to cause the direct current, having the magnitude configured to change based on the logic level of the second signal, to flow in the second line.
This invention relates to a receiving apparatus for communication systems, particularly those using direct current (DC) signals to transmit data. The problem addressed is the need for efficient and reliable data transmission over DC lines, where signal integrity and power management are critical. The receiving apparatus includes a second communicator that interfaces with a second line carrying a direct current (DC) signal. The second communicator contains a constant current circuit designed to regulate the DC flowing in the second line. The magnitude of this DC is dynamically adjusted based on the logic level of a second signal, allowing for controlled data transmission. This ensures stable communication while adapting to varying signal conditions. The apparatus also includes a first communicator that interfaces with a first line, where the first line carries a first signal with a first logic level. The first communicator is configured to detect changes in the first signal and generate a corresponding output. The second communicator, in response to the first communicator's output, adjusts the DC in the second line to reflect the logic level of the second signal. This interaction enables bidirectional communication, where data is transmitted and received over separate lines while maintaining signal integrity. The invention improves communication efficiency by dynamically adjusting current levels based on signal logic, reducing power consumption and enhancing reliability in DC-based communication systems.
12. A receiving apparatus comprising: a first signal inputter connected to a second line that is connected with an AC connection to a transmitting-side ground node, the transmitting-side ground node being configured to be supplied with a ground potential of the transmitting apparatus, the first signal inputter being configured to generate an output signal by canceling an AC potential difference from a first signal, on which the AC potential difference is multiplexed, by being connected to the ground potential of the transmitting apparatus via the second line, the AC potential difference being an alternating potential difference between the ground potential of the transmitting apparatus and a ground potential of the receiving apparatus, and to output the output signal; and a communicator that includes a constant current circuit configured to cause a direct current, having a magnitude configured to change based on a logic level of a second signal, to flow in the first line to thereby transmit the second signal from the receiving apparatus to the transmitting apparatus.
13. The receiving apparatus according to claim 10 , wherein the first signal inputter includes an operational amplifier including: a positive input terminal; a negative input terminal; and an output terminal connected to the negative input terminal via a resistance element; the first signal is supplied to the negative input terminal via a resistance element, a bias potential is supplied to the positive input terminal via at least a resistance element; and Z 2 p /Z 1 p and Z 2 n /Z 1 n are substantially equal to each other, where Z 1 p is an impedance of a side of the second line when viewed from the positive input terminal, Z 2 p is an impedance of a supply side configured to supply the bias potential when viewed from the positive input terminal, Z 1 n is an impedance of a supply side configured to supply the first signal when viewed from the negative input terminal, and Z 2 n is an impedance of the output terminal when viewed from the negative input terminal.
14. The receiving apparatus according to claim 10 , wherein the first signal inputter includes: an operational amplifier including: a negative input terminal; and a positive input terminal connected to the transmitting-side ground node with an AC connection via a resistance element and the second line, the positive input terminal being configured to be supplied with a bias potential, on which the AC potential difference is multiplexed, via a resistance element; a differential signal generating circuit configured to generate, based on the first signal, both a positive-phase signal and an inverted-phase signal obtained by inverting the positive-phase signal; a first buffer circuit configured to supply the positive-phase signal to one of the positive input terminal and the negative input terminal of the operational amplifier via a resistance element; and a second buffer circuit configured to supply the inverted-phase signal to the other one of the positive input terminal and the negative input terminal of the operational amplifier via a resistance element, and the second buffer circuit having an output impedance substantially equal to an output impedance of the first buffer circuit.
15. The receiving apparatus according to claim 10 , wherein the first signal inputter includes: an operational amplifier including: a negative input terminal; and a positive input terminal connected to the transmitting-side ground node with an AC connection via a resistance element and the second line; a first buffer circuit configured to supply the first signal to the negative input terminal of the operational amplifier via a resistance element; and a second buffer circuit configured to apply a bias potential, on which the AC potential difference is multiplexed, to the positive input terminal of the operational amplifier via a resistance element, and the second buffer circuit having an output impedance substantially equal to an output impedance of the first buffer circuit.
This invention relates to a receiving apparatus for differential signal transmission systems, addressing the challenge of accurately receiving signals while minimizing noise and distortion. The apparatus includes a first signal inputter that processes differential signals transmitted over two lines, where one line carries the signal and the other serves as a reference or ground. The first signal inputter contains an operational amplifier with a negative input terminal and a positive input terminal. The positive input terminal is connected to the transmitting-side ground node via an AC coupling resistance element and the second line, ensuring proper grounding while allowing AC signals to pass. A first buffer circuit supplies the first signal to the negative input terminal of the operational amplifier through a resistance element, while a second buffer circuit applies a bias potential with multiplexed AC potential differences to the positive input terminal via another resistance element. The second buffer circuit is designed to have an output impedance substantially equal to that of the first buffer circuit, ensuring balanced signal processing and reducing common-mode noise. This configuration enhances signal integrity and minimizes distortion in differential signal reception.
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February 16, 2021
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